JP2015121957A - Storage system, server, load balancing setting method, and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a storage system which properly sets load balancing of I/O processing with a simple configuration.SOLUTION: A storage system includes: a storage device; and a server which accesses one or a plurality of logical disks in the storage device via a plurality of redundant logical paths. The server includes: measurement means which measures I/O processing time of each of the logical disks, for each of the logical paths; determination means which determines whether there is a significant difference in processing time measured by the measurement means between the logical paths; and setting means which sets a logical path for I/O processing with respect to the logical disk on which the I/O processing time has been measured, on the basis of a result determined by the determination means.

Description

  The present invention relates to a storage system, a server, a load distribution setting method, and a control method.

  As the storage architecture becomes more complex, a method for easily selecting an access path to the storage has been considered in order to obtain optimum input / output performance.

  For example, Patent Document 1 discloses an efficient access path by changing the state of an access path having a high I / O (Input / Output) speed to an I / O usage state for each access path to each logical disk. A storage system that switches quickly is described.

  Patent Document 2 describes a storage system that sets an optimal command issue pattern for each external storage apparatus with respect to the main storage apparatus.

  Patent Document 3 describes that an optimum I / O configuration is determined by testing performance characteristics of a plurality of I / O operations.

  Patent Document 4 describes measuring the time length of a response to an IO command issued to an external storage system for each path element.

  Patent Document 5 describes a load distribution apparatus in which each of a plurality of nodes as a transfer destination of a plurality of tasks determines a load transfer destination based on impossibility information of the own node.

  Further, in Patent Document 6, based on the correlation between the propagation times of adjacent measurement packets, the available bandwidth of the network route is calculated from the magnitude relationship between the transmission speed of the measurement packet and the available bandwidth of the route. Describes a network communication performance measurement method for estimating.

JP 2012-212295 A JP 2010-26873 A JP 2009-163773 A JP 2007-179156 A Japanese Patent No. 4265377 Japanese Patent No. 3587352

  Storage types include symmetric storage and asymmetric storage depending on the cache structure. There is a big difference between a symmetric storage and an asymmetric storage with respect to a path for performing I / O (Input / Output) processing. The difference will be described with reference to FIGS.

  First, the configuration of the symmetric storage will be described with reference to FIG. FIG. 7 is a diagram illustrating an example of the configuration of a symmetric storage. As shown in FIG. 7, the symmetric storage 71 includes a controller # 71, a controller # 72, and a storage device 711. Here, it is assumed that the storage device 711 is one of LUNs (Logical Unit Numbers) obtained by logically dividing a logical HDD created from a plurality of physical HDDs (Hard Disk Drives). Hereinafter, the LUN is also referred to as a logical disk. A server 72 is connected to the symmetric storage 71. The server 72 includes a path control unit 721 that functions as control software that controls an access path (also simply referred to as a path) for accessing the storage device 711 of the symmetric storage 71.

  The controller # 71 and the controller # 72 of the symmetric storage 71 control the storage device 711. The controller # 71 and the controller # 72 are connected to the storage device 711. Controller # 71 and controller # 72 are connected to each other. The controller # 71 is provided with a cache # C71, and the controller # 72 is provided with a cache # C72. The cache # C71 and the cache # C72 are synchronized. Therefore, the data cached in the cache # C71 and the cache # C72 are the same.

  In the symmetric storage 71, in order to access a certain logical disk on the storage device 711, I / O processing is performed equivalently in terms of performance from a plurality of controller paths. This is because the data is synchronized in the caches of the plurality of controllers, so that the same data can be referred to when accessing from any controller.

  In the symmetric storage 71 of FIG. 7, the paths for the server 72 to access the storage device 711 include a path 1 that passes through the controller # 71 and a path 2 that passes through the controller # 72. The server 72 can obtain the same performance regardless of which path is used for I / O processing. In other words, when the symmetric storage 71 is used, a preferable load distribution setting for I / O processing is to set all the paths to be used.

  Next, the configuration of the asymmetric storage will be described with reference to FIG. FIG. 8 is a diagram illustrating an example of the configuration of an asymmetric storage.

  As shown in FIG. 8, the asymmetric storage 81 includes a controller # 81, a controller # 82, and a storage device 811. The storage device 811 is the same as the storage device 711 in FIG. A server 82 is connected to the asymmetric storage 81. The server 82 includes a path control unit 821 that functions as control software for controlling an access path for accessing the storage device 811 of the asymmetric storage 81.

  The controller # 81 and the controller # 82 of the asymmetric storage 81 control the storage device 811. Controller # 81 and controller # 82 are interconnected. The controller # 81 is provided with a cache # C81, and the controller # 82 is provided with a cache # C82. Unlike the symmetric storage 71, the cache # C81 and the cache # C82 are not synchronized.

  In the asymmetric storage 81, each logical disk is linked to one of the caches provided in the controller. Since the caches are not synchronized, the performance differs depending on which controller performs the I / O processing.

  The storage device 811 (logical disk) shown in FIG. 8 is linked to the cache # C81 of the controller # 81. Therefore, the cache used for the I / O processing is the cache # C81 of the controller # 81, and the cache # C82 of the controller # 82 is not used. As shown in FIG. 8, the path 1 is a path for accessing the storage device 811 via the controller # 81. Path 2 is a path for accessing the storage device 811 from the controller # 82 via the interconnect. Therefore, the performance of the I / O process using the path 1 using the controller # 81 is better than the I / O process using the path 2. In addition, there is a significant difference in processing time between the I / O processing using path 1 and the I / O processing using path 2. Therefore, when the asymmetric storage 81 is used, a preferable load distribution setting for the I / O processing is to use the path 1 in FIG.

  Currently, there is a tendency to improve the performance of the entire storage by reducing the cache load, and asymmetric storage is increasing. For this reason, it is important in terms of performance to control which path (which controller) the server performs I / O processing through. Therefore, it is necessary to perform load distribution setting for I / O processing using a path that can obtain optimum performance.

  The cache method differs depending on the storage vendor and storage type. Therefore, in order to perform the optimal load distribution setting for I / O processing, it is necessary to consider information such as the cache structure of each storage and the disk arrangement indicating which cache the logical disk is associated with.

  However, the technologies of Patent Documents 1 to 6 do not take into account the architecture such as the storage cache structure and disk arrangement.

  In order to obtain optimum I / O performance in consideration of the storage architecture, a mechanism for acquiring architecture information such as the storage cache structure and disk arrangement must be implemented on the server side.

  The present invention has been made in view of the above problems, and an object of the present invention is to realize a storage system that performs load distribution setting for suitable I / O processing with a simpler configuration.

  A storage system according to an aspect of the present invention includes a storage apparatus and a server that accesses one or more logical disks in the storage apparatus via a plurality of redundant logical paths, and the server includes: For each logical disk, there is a significant difference in the processing time measured by the measuring means between the measuring means for measuring the processing time of the I / O processing of the logical disk for each logical path and the logical path. Determining means for determining whether or not, and setting means for setting a logical path for performing the I / O processing on the logical disk for which the processing time of the I / O processing has been measured based on the determination result of the determining means And comprising.

  A server according to an aspect of the present invention is a server that accesses one or a plurality of logical disks in a storage apparatus via a plurality of redundant logical paths, and each logical disk includes an I of the logical disk. Measuring means for measuring the processing time of each / O process for each logical path, determining means for determining whether there is a significant difference in the processing time measured by the measuring means between the logical paths, Setting means for setting a logical path for performing the I / O processing on the logical disk for which the processing time of the I / O processing is measured based on the determination result of the determination means.

  A storage system load distribution setting method according to an aspect of the present invention includes a storage apparatus and a server that accesses one or more logical disks in the storage apparatus via a plurality of redundant logical paths. The load distribution setting method for a storage system, wherein the server measures the processing time of I / O processing of the logical disk for each logical path for each logical disk, and measures the measurement between the logical paths. It is determined whether there is a significant difference in the processing time, and based on the determination result, a logical path for performing the I / O processing is set for the logical disk for which the processing time of the I / O processing is measured. Do.

  A server control method according to an aspect of the present invention is a server control method for accessing one or a plurality of logical disks in a storage apparatus via a plurality of redundant logical paths, and for each logical disk The processing time of the I / O processing of the logical disk is measured for each logical path, it is determined whether there is a significant difference in the measured processing time between the logical paths, and based on the determination result Then, the logical path for performing the I / O processing is set for the logical disk for which the processing time of the I / O processing is measured.

  According to the present invention, it is possible to perform load distribution setting for suitable I / O processing with a simpler configuration.

It is a figure which shows an example of a structure of the storage system which concerns on 1st Embodiment. It is a functional block diagram which shows an example of the function structure of the server in the storage system which concerns on 1st Embodiment. It is a flowchart which shows an example of the flow of the load distribution setting process of the server in the storage system which concerns on 1st Embodiment. It is a figure which shows an example of a structure of the storage system which concerns on 2nd Embodiment. It is a functional block diagram which shows an example of the function structure of the server in the storage system which concerns on 2nd Embodiment. It is a figure which shows an example of the hardware constitutions of the server which can implement | achieve the storage system which concerns on each embodiment of this invention. It is a figure for demonstrating an example of a structure of object storage. It is a figure for demonstrating an example of a structure of asymmetrical storage.

<First Embodiment>
An embodiment of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a diagram showing a configuration of a storage system 1 according to the present embodiment. As shown in FIG. 1, the storage system 1 according to the present embodiment includes a server 10A, a server 10B, a switch 20A, a switch 20B, a storage device 30A, and a storage device 30B. In this embodiment, the number of servers, the number of switches, and the number of storage apparatuses are described as two examples, but these numbers are only examples and are not limited thereto. It is not something.

  In the present embodiment, server 10A and server 10B are collectively referred to as server 10. Similarly, the switch 20A and the switch 20B are collectively referred to as a switch 20, and the storage device 30A and the storage device 30B are collectively referred to as a storage device 30.

  The server 10A and the server 10B are equipped with at least one path control SW (SoftWare). The path control SW controls an access path (hereinafter referred to as a logical path) for accessing the storage device 31A in the storage device 30A and / or the storage device 31B in the storage device 30B. In FIG. 1, a configuration in which one path control SW is mounted will be described as an example. However, a plurality of path control SWs can be mounted on the same server.

  Server 10A and server 10B are physically connected to switch 20A and switch 20B. Further, the switch 20A and the switch 20B are redundantly connected to the controllers provided in the storage device 30A and the storage device 30B.

  Generally, when performing path redundancy between a plurality of servers 10 and the storage device 30, the switch 20 is used. Therefore, in FIG. 1, a configuration in which the switch 20 is included between the server 10 and the storage device 30 will be described as an example. However, the server 10 and the storage device 30 may be directly connected.

  The storage device 30A includes a controller # A1, a controller # A2, and a storage device 31A. Similarly, the storage device 30B includes a controller # B1, a controller # B2, and a storage device 31B.

  The controller # A1 and controller # A2 of the storage device 30A control the storage device 31A. Further, the controller # A1 is provided with a cache # AC1, and the controller # A2 is provided with a cache # AC2.

  Similarly, the controller # B1 and the controller # B2 of the storage device 30B control the storage device 31B. Further, the controller # B1 is provided with a cache # BC1, and the controller # B2 is provided with a cache # BC2.

  Generally, a storage device has two or more controllers. In general, each controller has one cache. Therefore, although FIG. 1 shows a configuration in which each storage device includes two controllers each having one cache, the present invention is not limited to this.

  Also, as shown in FIG. 1, the controllers (between controller # A1 and controller # A2 and between controller # B1 and controller # B2) are connected by a communicable interface. The storage apparatuses (between the storage apparatus 30A and the storage apparatus 30B) are connected by a communicable interface.

  Each controller has two ports for connecting to other devices. Note that the number of ports included in each controller is not limited to this.

  The storage device 31A and the storage device 31B are configured by a plurality of LUNs (Logical Unit Numbers) obtained by logically dividing a logical HDD created from a plurality of physical HDDs (Hard Disk Drives). Hereinafter, the LUN is also referred to as a logical disk. As shown in FIG. 1, in this embodiment, it is assumed that the storage device 31A and the storage device 31B each include N LUNs (LUN # 1 to LUN # N). Note that the number of LUNs may be one or more. In addition, the number of LUNs of the storage device 31A and the storage device 31B is described as an example, but the number may be different.

  In the present embodiment, it is assumed that the N LUNs included in the storage device 31A are associated with the cache # AC1 and / or the cache # AC2, respectively. Similarly, it is assumed that N LUNs included in the storage device 31B are associated with the cache # BC1 and / or the cache # BC2, respectively.

  Further, in the present embodiment, as shown by the broken line in FIG. 1, each LUN can be applied even when it has a RAID (Redundant Arrays of Independent Disks) configuration across storage apparatuses.

  In FIG. 1, the interface and protocol used for communication between the server 10 and the switch 20 are not particularly limited. Similarly, the interface and protocol between the switch 20 and the storage apparatus 30 and between the storage apparatuses are not particularly limited.

(Functional configuration of server 10)
Next, the functional configuration of the server 10 of the storage system 1 according to the present embodiment will be described with reference to FIG. FIG. 2 is a functional block diagram showing a functional configuration of the server 10 in the storage system 1 according to the present embodiment. The functional configuration of the server 10 in FIG. 2 is the functional configuration of both the server 10A and the server 10B.

  As illustrated in FIG. 2, the server 10 includes a measurement unit 11, a management unit 13, a determination unit 14, and a setting unit 15. The measurement unit 11, the management unit 13, the determination unit 14, and the setting unit 15 function as the path control SW described above.

  The measuring unit 11 is means for measuring the processing time of the I / O processing of each logical disk for each logical path. The measurement unit 11 includes a writing unit 111 and a reading unit 112.

  The writing unit 111 is means for writing data to a plurality of logical disks (LUN # 1 to #N). Specifically, the writing unit 111 writes test data used when measuring the processing time of the I / O processing in a predetermined area of a certain logical disk among a plurality of logical disks. The predetermined area in which the test data is written is preferably at the same position in each logical disk, for example. Also, the predetermined area is preferably an area that is sequentially free for each logical disk, such as the last block of each logical disk. Thereby, the difference in processing performance of I / O processing due to writing in different areas can be reduced. Hereinafter, a predetermined area in which test data in each logical disk is written is referred to as a specific area.

  In addition, the writing unit 111 refers to the information on the logical path managed by the management unit 13 in order to measure the processing time (write processing time) of the test data writing I / O processing, and for each logical path, Write test data to a specific area of the logical disk. Then, the writing unit 111 measures the test data writing processing time. Note that the writing unit 111 performs the write I / O processing for one logical path a predetermined number of times, and uses, for example, a statistical method such as taking an average value of the write processing time to calculate the average write processing time of the logical path. Is preferably calculated for each logical path. Note that, as an example of a statistical method for calculating the write processing time, an example has been described in which the average value of the write processing time is taken. However, the present invention is not limited to this, and other methods are used to write data. Processing time may be calculated.

  The writing unit 111 supplies the calculated writing processing time to the determination unit 14.

  The reading unit 112 refers to the information on the logical path managed by the management unit 13 and reads the test data written by the writing unit 111 for each logical path. Then, the reading unit 112 measures the processing time (reading processing time) of the test data reading I / O processing. Note that the reading unit 112 performs read I / O processing for one logical path a predetermined number of times, and uses, for example, a statistical method such as taking an average value of the read processing time to read the average read processing time of the logical path. Is preferably calculated for each logical path. Note that, as an example of a statistical method for calculating the read processing time, an example has been described in which an average value of the read processing time is taken. However, the present invention is not limited to this, and other methods are used for reading. Processing time may be calculated.

  The reading unit 112 supplies the calculated read processing time to the determination unit 14.

  The management unit 13 manages information indicating logical paths for accessing each logical disk from the server 10. Information regarding the logical path managed by the management unit 13 may be stored in the management unit 13 or may be stored in a storage member separate from the management unit 13.

  The determination unit 14 receives the write processing time for each logical path from the writing unit 111. Further, the determination unit 14 receives the read processing time for each logical path from the read unit 112. The determination unit 14 determines whether or not there is a significant difference between the read processing times of the read I / O for each logical path between the logical paths using a statistical method. In addition, the determination unit 14 determines whether or not there is a significant difference between the logical I / O write processing times for each logical path using a statistical method.

  When there is no significant difference in the read processing time between all the logical paths and no significant difference in the write processing time, the determination unit 14 determines that the storage type of the logical disk on which the test data is written and read is symmetric storage. Presume that there is.

  When the determination result indicates that the read processing time and / or the write processing time have a significant difference between the logical paths, the determination unit 14 reads the logical path having a significant difference from the other logical paths. Check the processing time and write processing time. When the logical path read processing time is shorter than the other logical paths and the logical path write processing time is longer than the other logical paths, or vice versa, the determination unit 14 stores the logical disk storage. Estimate that the type is neither symmetric storage nor asymmetric storage. Hereinafter, when the read processing time is shorter than the predetermined time (the read I / O processing is fast), the performance of the read I / O processing is also good. Further, when the write processing time is shorter than a predetermined time (the write I / O process is fast), it is also said that the performance of the write I / O process is good.

  When the logical disk is asymmetric storage, there is generally a logical path in which the read and write processing times are shorter than the read and write processing times in other logical paths. However, when another device is set between the server and the controller, there is a high possibility that this is not the case. Therefore, it cannot be confirmed from the read processing time and the write processing time whether the logical disk from which the test data is read and written is a symmetric storage. Therefore, in the above state, the determination unit 14 estimates that the logical disk storage type is neither symmetric storage nor asymmetric storage.

  In addition, the determination unit 14 determines that there is a significant difference in one of the read processing time and the write processing time, or there is a significant difference in both the read processing time and the write processing time. The storage type is estimated to be asymmetric storage. That is, in a specific logical path, (1) performance of read I / O processing and write I / O processing is good, (2) performance of read I / O processing is good, and there is no significant difference in write processing time ( 3) When the performance of the write I / O processing is good and there is no significant difference in the read processing time, the determination unit 14 estimates that the storage type of the logical disk is asymmetric storage.

  Then, the determination unit 14 supplies the estimation result of the storage type of the logical disk to the setting unit 15 for each logical disk. When the determination unit 14 estimates that the storage type of the logical disk is asymmetric storage, the information indicating a specific logical path with good read I / O processing and / or write I / O processing along with the estimation result Is supplied to the setting unit 15. The specific logical path may be one or plural.

  The setting unit 15 performs load distribution setting for the logical disk based on the estimation result of the storage type of the logical disk from the determination unit 14. Specifically, when the storage type is symmetric storage, or when the storage type is neither symmetric storage nor asymmetric storage, the setting unit 15 performs I / O processing using all logical paths for the logical disk. Set as follows. Further, when the storage type is asymmetric storage, the setting unit 15 uses a specific logical path with good I / O processing performance indicated by the information supplied together with the determination result from the determination unit 14 to perform I / O Set to process.

(Operation of server 10)
Next, the operation of the server 10 of the storage system 1 according to this embodiment will be described with reference to FIG. FIG. 3 is a flowchart showing an example of a flow of load distribution setting processing for a logical disk in the server 10 of the storage system 1 according to the present embodiment.

  Here, for convenience of explanation, the case where test data is written to LUN # 1 of the storage device 31A of the storage device 30A among a plurality of logical disks will be described as an example.

  Step S1: The writing unit 111 writes test data in a specific area of LUN # 1.

  Step S2: The reading unit 112 reads the test data written in step S1 by the writing unit 111 for each logical path for the LUN # 1 managed by the management unit 13, and measures the read processing time of the test data. To do. At this time, it is preferable that the read I / O processing is performed a predetermined number of times for one logical path, and the processing for calculating the read processing time is performed for each logical path using a statistical method.

  Step S3: The writing unit 111 writes test data to a specific area of LUN # 1 for each logical path managed by the management unit 13, and measures the write processing time of the test data. Note that the test data used in step S3 may be the same as or different from the test data used in step S1. Further, the specific area where the test data is written may be the same area as the specific area where the test data is written in step S1, or may be a different area. Further, similarly to step S2, it is preferable that the write I / O process is performed a predetermined number of times for one logical path, and the process of calculating the write process time is performed for each logical path using a statistical method.

  Note that step S3 may be performed before step S1. Further, when step S3 is performed before step S1, measurement of the read processing time (step S2) may be performed using the test data written in step S3.

  Step S4: The determination unit 14 determines whether or not there is a significant difference in the read processing time of the read I / O for each logical path, using a statistical method. Further, the determination unit 14 determines whether or not there is a significant difference in the write I / O write processing time for each logical path using a statistical method. If there is no significant difference in the read processing time between all the logical paths and no significant difference in the write processing time (in the case of NO), the process proceeds to step S5. If there is a significant difference in at least one of the read processing time and the write processing time (in the case of YES), the process proceeds to step S6.

  Step S5: The setting unit 15 sets LUN # 1 to perform I / O processing using all logical paths, and ends the load distribution setting processing. Thereby, the load distribution setting of the I / O processing is performed.

  Step S6: The determination unit 14 confirms the read processing time and the write processing time of the logical path that has a significant difference from other logical paths. If the logical path read processing time is shorter than the other logical paths and the logical path write processing time is longer than the other logical paths, or vice versa (YES), step S5. Proceed to In step S5, the setting unit 15 sets LUN # 1 to perform I / O processing using all paths. In other cases (NO), the process proceeds to step S7.

  Step S7: The setting unit 15 uses the specific logical path with the performance of the read I / O process and / or the write I / O process better than other logical paths for the LUN # 1. And finish the load distribution setting process. Thereby, the load distribution setting of the I / O processing is performed.

  The server 10 performs the processes in steps S1 to S7 on all logical disks.

  In the above process, it is preferable that no load is applied to the server 10 and the storage apparatus 30 that manages the logical disk to be processed. This is because the I / O response time may be disturbed by the influence of the load (disturbance) because the symmetric / asymmetric storage is estimated by measuring the processing time of the I / O processing. .

(effect)
According to the storage system 1 according to the present embodiment, it is possible to perform a suitable load distribution setting for I / O processing with a simpler configuration.

  This is because the measurement unit 11 of the server 10 that accesses the logical disk in the storage device 30 through the plurality of redundant logical paths determines the logical disk I / O processing time for each logical disk. The determination unit 14 determines whether or not there is a significant difference in processing time between logical paths, and the setting unit 15 determines the I / I for the logical disk whose processing time is measured based on the determination result. This is because the logical path for performing the O process is set.

  When the storage type of the logical disk is symmetric storage, there is no significant difference in the processing time of I / O processing between logical paths. On the other hand, when the storage type of the logical disk is asymmetric storage, there is a significant difference in the processing time of I / O processing between logical paths.

  Accordingly, the setting unit 15 sets the logical path based on whether there is a significant difference in the processing time between logical paths, thereby significantly different from the logical disk having a significant difference in the processing time. Different logical paths can be set for logical disks with no difference. As a result, the storage system 1 can suitably perform load distribution settings for I / O processing.

  Further, the determination unit 14 estimates the storage type of the logical disk based on the processing time of the I / O processing. That is, the determination unit 14 can estimate which cache is used by the logical disk.

  As a result, the server 10 does not receive the architecture information such as the logical disk cache structure and disk arrangement necessary for setting the logical path from which the optimum I / O performance can be obtained from the storage 30. On the other hand, it is possible to set load distribution using an optimal logical path.

  Therefore, the server 10 is optimal without implementing a mechanism for exchanging architecture information, regardless of whether the storage type of the logical disk in the storage device 30 is a symmetric storage or an asymmetric storage structure. I / O performance can be obtained.

  In addition, since the server 10 does not need to acquire information specific to the storage device 30, application in a multi-vendor storage environment is possible. That is, the server 10 does not need to prepare path control SWs separately according to the types of logical disks. In addition, the server 10 can set the optimum I / O load distribution for the logical disks in all the storage devices with one path control SW.

  Further, according to the storage system 1 according to the present embodiment, even when the structure of the logical disk in the storage device 30 becomes invisible from the server 10 side, I / O load distribution is performed using an optimum path. It can be performed. This is because the server 10 estimates whether the logical disk to be managed is symmetric storage or asymmetric storage as described above without exchanging information with the storage device 30.

  When the determination unit 14 estimates that the storage type of the logical disk is symmetric storage, the setting unit 15 performs the logical path so that the logical disk performs I / O processing using all the logical paths. Set up. In the case of symmetric storage, I / O processing is performed equivalently in terms of performance regardless of which of the plurality of logical paths for accessing the logical disk. Therefore, when the setting unit 15 performs the setting as described above, the server 10 can perform I / O processing using all logical paths for the logical disk estimated to be symmetric storage. Thereby, the storage system 1 can perform load distribution setting of I / O processing more preferably.

  When the determination unit 14 estimates that the storage type of the logical disk is asymmetric storage, the setting unit 15 performs I / O processing using a logical path whose performance of I / O processing is better than that of other logical paths. Set the logical path as you do. In the case of asymmetric storage, the performance of I / O processing differs for each of a plurality of logical paths for accessing a logical disk. Therefore, setting by the setting unit 15 as described above allows the server 10 to perform I / O processing using a logical path with good I / O processing performance. That is, the server 10 does not perform I / O processing using a logical path with poor I / O processing performance. Thereby, the storage system 1 can perform the load distribution setting of the I / O processing more preferably.

(Modification)
In the first embodiment, the read I / O process and the write I / O process have been described as an example in which the load distribution setting is performed using the same logical path. Is not limited to this. The logical path for performing the read I / O process may be different from the logical path for performing the write I / O process.

  Consider a case where there is no significant difference in the processing time of the read I / O process and the significant difference in the processing time of the write I / O process between logical paths for a certain logical disk (for example, LUN # 1). . In this case, in the actual data I / O processing, the setting unit 15 of the server 10 sets so that all logical paths are used for the read I / O processing, and a high-performance path for the write I / O processing. Set to use.

  In this case, the setting unit 15 determines whether the type of the I / O process is a read I / O process or a write I / O process, and performs the logical path setting.

  As described above, by setting the logical path used in each case of the read I / O process and the write I / O process, the storage system 1 has the effect according to the first embodiment described above. Path resources can be used without leaving them.

<Second Embodiment>
Next, a second embodiment of the present invention will be described in detail with reference to the drawings. For convenience of explanation, members having the same functions as those included in the drawings described in the first embodiment are given the same reference numerals, and detailed descriptions thereof are omitted.

  First, the configuration of the storage system 2 according to the present embodiment will be described with reference to FIG. FIG. 4 is a diagram showing a configuration of the storage system 2 according to the present embodiment. As shown in FIG. 4, the storage system 2 according to the present embodiment includes a server 10 and a storage device 30.

  The server 10 is equipped with at least one path control SW. The path control SW controls a logical path for accessing the storage device 31 in the storage device 30.

  The server 10 is redundantly connected to the LUN of the storage device 31 via the controller # A1 provided in the storage device 30.

  The storage device 30 includes a controller # A1, a controller # A2, and a storage device 31. The controller # A1 and the controller # A2 of the storage device 30 control the storage device 31. Further, the controller # A1 is provided with a cache # AC1, and the controller # A2 is provided with a cache # AC2.

  The controllers (between controller # A1 and controller # A2) are connected by a communicable interface.

  The storage device 31 is configured by one or a plurality of LUNs obtained by logically dividing a logical HDD created from a plurality of physical HDDs. Although one LUN is shown in FIG. 4, the present invention is not limited to this. LUN # 1 included in the storage device 31 is linked to the cache # AC1 and / or the cache # AC2.

  Next, the functional configuration of the server 10 of the storage system 2 according to the present embodiment will be described with reference to FIG. FIG. 5 is a functional block diagram showing a functional configuration of the server 10 in the storage system 2 according to the present embodiment.

  As illustrated in FIG. 5, the server 10 includes a measurement unit 11, a determination unit 14, and a setting unit 15. The measurement unit 11, the determination unit 14, and the setting unit 15 function as the path control SW described above.

  The measurement unit 11 corresponds to the measurement unit 11 in the first embodiment. The measurement unit 11 measures the I / O processing time of the logical disk for each logical path for each logical disk. The measurement unit 11 supplies the measured processing time to the determination unit 14.

  The determination unit 14 corresponds to the determination unit 14 in the first embodiment. The determination unit 14 determines whether there is a significant difference in processing time between logical paths measured by the measurement unit 11. The determination unit 14 supplies the determined result to the setting unit 15.

  The setting unit 15 corresponds to the setting unit 15 in the first embodiment. Based on the determination result of the determination unit 14, the setting unit 15 sets the logical path for performing the I / O processing on the logical disk (LUN # 1 in FIG. 5) whose I / O processing time is measured. Do.

  For example, when the determination unit 14 determines that there is no significant difference in processing time between logical paths, the setting unit 15 performs an I / O process using all logical paths for LUN # 1. Set the logical path.

  Further, when the determination unit 14 determines that there is a significant difference in processing time between logical paths, the setting unit 15 performs a logical operation with better I / O processing performance than LUN # 1 for other logical paths. A logical path is set so that I / O processing is performed using the path.

(effect)
According to the storage system 2 according to the present embodiment, it is possible to perform a suitable load distribution setting for I / O processing with a simpler configuration.

  This is because the measurement unit 11 of the server 10 that accesses the logical disk in the storage device 30 through the plurality of redundant logical paths determines the logical disk I / O processing time for each logical disk. The determination unit 14 determines whether or not there is a significant difference in processing time between logical paths, and the setting unit 15 determines the I / I for the logical disk whose processing time is measured based on the determination result. This is because the logical path for performing the O process is set.

  When the storage type of the logical disk is symmetric storage, there is no significant difference in the processing time of I / O processing between logical paths. On the other hand, when the storage type of the logical disk is asymmetric storage, there is a significant difference in the processing time of I / O processing between logical paths.

  Accordingly, the setting unit 15 sets the logical path based on whether there is a significant difference in the processing time between logical paths, thereby significantly different from the logical disk having a significant difference in the processing time. Different logical paths can be set for logical disks with no difference. As a result, the storage system 2 can suitably perform load distribution settings for I / O processing.

(About hardware configuration)
Each part of the server shown in FIGS. 2 and 5 is realized by the hardware resource illustrated in FIG. That is, the configuration shown in FIG. 6 includes a RAM (Random Access Memory) 101, a ROM (Read Only Memory) 102, a communication interface 103, a storage medium 104, and a CPU 105. The CPU 105 controls the overall operations of the compiler and the job scheduler by reading various software programs (computer programs) stored in the ROM 102 or the storage medium 104 into the RAM 101 and executing them. In other words, in each of the above embodiments, the CPU 105 executes a software program that executes each function (each unit) included in the compiler and the job scheduler while appropriately referring to the ROM 102 or the storage medium 104.

  Further, in each of the above-described embodiments, the case where the functions shown in each block in the server shown in FIGS. 2 and 5 are realized by a software program as an example executed by the CPU 105 shown in FIG. 6 has been described. However, some or all of the functions shown in the blocks shown in FIGS. 2 and 5 may be realized as hardware.

  Further, in the present invention described by taking each embodiment as an example, a computer program capable of realizing the functions described above is supplied to the compiler and job scheduler, and then the CPU 105 reads the computer program into the RAM 101 and executes it. Is achieved.

  The supplied computer program may be stored in a computer-readable storage device such as a readable / writable memory (temporary storage medium) or a hard disk device. In such a case, the present invention can be understood as being configured by a code representing the computer program or a storage medium storing the computer program.

  Each of the above-described embodiments is a preferred embodiment of the present invention, and the scope of the present invention is not limited only to the above-described embodiments, and those skilled in the art do not depart from the gist of the present invention. However, it is possible to construct a form in which various modifications are made by correcting or substituting the above-described embodiments.

  When viewed from the path control SW on the server, the present invention is logically connected to a logical disk that is connected to a storage device connected to the server through a physically redundant path and is managed by the storage device. It can be suitably applied in an environment connected by redundant paths.

  A part or all of the above embodiments can be described as in the following supplementary notes, but is not limited thereto.

  (Supplementary Note 1) A storage apparatus and a server that accesses one or a plurality of logical disks in the storage apparatus via a plurality of redundant logical paths, wherein the server includes the server for each logical disk. A determination unit that measures the processing time of the I / O processing of the logical disk for each logical path, and a determination that determines whether or not there is a significant difference in the processing time measured by the measuring unit between the logical paths And setting means for setting a logical path for performing the I / O processing on the logical disk for which the processing time of the I / O processing is measured based on the determination result of the determination means. And storage system.

  (Supplementary note 2) When the determination result of the determination means is that there is no significant difference, the setting means uses all the logical paths for the logical disk for which the processing time of the I / O processing is measured. The storage system according to appendix 1, wherein a logical path is set so as to perform I / O processing.

  (Additional remark 3) When the determination result of the said determination means has the said significant difference, the said setting means is the performance of I / O processing with respect to the logical disk which measured the processing time of the said I / O processing. The storage system according to appendix 1 or 2, wherein the logical path is set so that I / O processing is performed using a logical path better than other logical paths.

  (Additional remark 4) The said measurement means measures the processing time of the read I / O process of the said logical disk, and the processing time of the write I / O process of the said logical disk for every said logical path for every logical disk. Whether the determination means has a significant difference between the processing time of the read I / O process and the processing time of the write I / O process measured by the measurement means between the logical paths. And the setting means determines the processing time of the I / O process based on the determination result for the processing time of the read I / O process and the determination result for the processing time of the write I / O process. 4. The storage system according to any one of appendices 1 to 3, wherein a logical path for performing an I / O process is set for the logical disk that has been measured.

  (Supplementary Note 5) When the determination result with respect to the processing time of the read I / O process and the determination result with respect to the processing time of the write I / O process are the results that there is no significant difference, The logical path is set so that the read I / O process and the write I / O process are performed using all the logical paths for the logical disk for which the processing time of the O process is measured. The storage system according to appendix 4.

  (Supplementary Note 6) When the determination means has a result that at least one of the determination result with respect to the processing time of the read I / O process and the determination result with respect to the processing time of the write I / O process has the significant difference, The processing time of the read I / O process and the processing time of the write I / O process are confirmed, and there is a logical path in which one processing time is shorter than the other logical path and the other processing time is longer than the other logical path. If there is a logical path for the logical disk for which the processing time of the I / O processing is measured, the setting means uses all the logical paths to perform read I / O processing and writing. When a logical path is set so as to perform I / O processing, and there is no logical path, read I / O processing and writing are performed using a logical path whose performance of I / O processing is better than other logical paths. I / Processing to perform, to set the logical paths, and wherein the storage system according to appendix 4 or 5.

  (Supplementary note 7) The server further includes management means for managing, for each logical disk, information indicating a plurality of logical paths for accessing each logical disk from the server, and the measuring means includes an I of the logical disk. The storage system according to any one of appendices 1 to 6, wherein a processing time of / O processing is measured for each of a plurality of logical paths managed by the management unit with respect to the logical disk. .

  (Supplementary Note 8) When the determination result of the determination means is that there is no significant difference, the setting means indicates that the storage type of the logical disk for which the processing time of the I / O processing is measured is the logical disk Any one of appendices 1 to 7, characterized in that it is estimated that the storage is a symmetric storage in which any of a plurality of logical paths for access is equivalently performed in terms of performance. Storage system.

  (Supplementary note 9) When the determination result of the determination means is that there is a significant difference, the setting means indicates that the storage type of the logical disk for which the processing time of the I / O processing is measured is the logical disk The storage system according to any one of appendices 1 to 8, wherein the storage system is presumed to be an asymmetric storage having different I / O processing performance for each of a plurality of logical paths to be accessed.

  (Supplementary Note 10) A server that accesses one or a plurality of logical disks in a storage apparatus via a plurality of redundant logical paths, and the processing time of I / O processing of the logical disk for each logical disk Measurement means for measuring each logical path, determination means for determining whether there is a significant difference in the processing time measured by the measurement means between the logical paths, and a determination result of the determination means And a setting unit configured to set a logical path for performing the I / O processing on the logical disk for which the processing time of the I / O processing is measured.

  (Additional remark 11) The said setting means uses all the logical paths with respect to the logical disk which measured the processing time of the said I / O process, when the determination result of the said determination means is a result without the said significant difference. The server according to appendix 10, wherein a logical path is set so as to perform I / O processing.

  (Additional remark 12) When the determination result of the said determination means has the said significant difference, the said setting means is the performance of I / O processing with respect to the logical disk which measured the processing time of the said I / O processing. 12. The server according to appendix 10 or 11, wherein the logical path is set so that I / O processing is performed using a logical path better than other logical paths.

  (Supplementary Note 13) For each logical disk, the measurement unit measures the processing time of the logical disk read I / O processing and the processing time of the logical disk write I / O processing for each logical path. Whether the determination means has a significant difference between the processing time of the read I / O process and the processing time of the write I / O process measured by the measurement means between the logical paths. And the setting means determines the processing time of the I / O process based on the determination result for the processing time of the read I / O process and the determination result for the processing time of the write I / O process. 13. The server according to any one of appendices 10 to 12, wherein a logical path for performing an I / O process is set for the logical disk that has been measured.

  (Supplementary Note 14) When the determination result with respect to the processing time of the read I / O process and the determination result with respect to the processing time of the write I / O process are the results that there is no significant difference, The logical path is set so that the read I / O process and the write I / O process are performed using all the logical paths for the logical disk for which the processing time of the O process is measured. The server according to attachment 13.

  (Supplementary Note 15) When at least one of the determination result with respect to the processing time of the read I / O process and the determination result with respect to the processing time of the write I / O process is the result that the significant difference exists, The processing time of the read I / O process and the processing time of the write I / O process are confirmed, and there is a logical path in which one processing time is shorter than the other logical path and the other processing time is longer than the other logical path. If there is a logical path for the logical disk for which the processing time of the I / O processing is measured, the setting means uses all the logical paths to perform read I / O processing and writing. When a logical path is set so as to perform I / O processing, and there is no logical path, read I / O processing and writing are performed using a logical path whose performance of I / O processing is better than other logical paths. I O processing to perform, to set the logical paths, and wherein the server according to Appendix 13 or 14.

  (Additional remark 16) The management means which manages the information which shows the several logical path for accessing each logical disk from the said server for every logical disk is further provided, The said measurement means is the I / O process of the said logical disk. 16. The server according to any one of appendices 10 to 15, wherein the processing time is measured for each of a plurality of logical paths managed by the management unit with respect to the logical disk.

  (Supplementary Note 17) When the determination result of the determination means is that there is no significant difference, the setting means indicates that the storage type of the logical disk for which the processing time of the I / O processing is measured is the logical disk Any one of appendices 10 to 16, wherein the storage is estimated to be a symmetric storage, in which any of a plurality of logical paths for access is equivalently performed in terms of performance. Server.

  (Supplementary Note 18) When the determination result of the determination means is that there is a significant difference, the setting means indicates that the storage type of the logical disk for which the processing time of the I / O processing is measured is the logical disk 18. The server according to any one of appendices 10 to 17, wherein the server is estimated to be an asymmetric storage having different I / O processing performance for each of a plurality of logical paths to be accessed.

  (Supplementary note 19) A load distribution setting method for a storage system comprising a storage device and a server that accesses one or more logical disks in the storage device via a plurality of redundant logical paths, The server measures the processing time of the I / O processing of the logical disk for each logical path for each logical disk, and whether there is a significant difference in the measured processing time between the logical paths. And setting a logical path for performing I / O processing on the logical disk for which the processing time of the I / O processing is measured based on the determination result.

  (Supplementary note 20) A server control method for accessing one or a plurality of logical disks in a storage apparatus via a plurality of redundant logical paths, wherein the logical disk I / O process is performed for each logical disk Is measured for each logical path, and it is determined whether there is a significant difference in the measured processing time between the logical paths. Based on the determination result, the processing of the I / O processing is determined. A control method comprising: setting a logical path for performing I / O processing on a logical disk whose time has been measured.

  (Supplementary Note 21) For each logical disk, the server that accesses one or more logical disks in the storage apparatus via a plurality of redundant logical paths is provided with the processing time of the logical disk I / O processing. Processing for measuring each logical path, processing for determining whether or not the measured processing time has a significant difference between the logical paths, and processing time for the I / O processing based on the determination result A program for executing a process for setting a logical path for performing an I / O process on a logical disk for which measurement is performed.

  (Supplementary note 22) A computer-readable recording medium storing the program according to supplementary note 21.

DESCRIPTION OF SYMBOLS 1 Storage system 10 Server 11 Measuring part 111 Writing part 112 Reading part 13 Management part 14 Judgment part 15 Setting part 20 Switch 30 Storage apparatus 31 Storage apparatus 2 Storage system

Claims (10)

A storage device and a server that accesses one or more logical disks in the storage device via a plurality of redundant logical paths;
The server
Measuring means for measuring the processing time of the I / O processing of the logical disk for each logical path for each logical disk;
Determining means for determining whether there is a significant difference in the processing time measured by the measuring means between the logical paths;
Storage comprising: setting means for setting a logical path for performing I / O processing on a logical disk for which the processing time of the I / O processing is measured based on a determination result of the determination means system.   When the determination result of the determination means is that there is no significant difference, the setting means uses all logical paths for the logical disk for which the processing time of the I / O processing is measured. 2. The storage system according to claim 1, wherein logical paths are set so as to perform O processing.   When the determination result of the determination means is that there is a significant difference, the setting means has a performance of the I / O process other than the logical disk on which the processing time of the I / O process is measured. The storage system according to claim 1 or 2, wherein the logical path is set so that I / O processing is performed using a logical path better than the path. The measuring means measures, for each logical path, the processing time of the logical disk read I / O processing and the processing time of the logical disk write I / O processing for each logical path,
Whether the determination unit has a significant difference between the processing time of the read I / O process and the processing time of the write I / O process measured by the measurement unit between the logical paths. Determine whether
The setting means sets the logical disk having measured the processing time of the I / O process based on the determination result with respect to the processing time of the read I / O process and the determination result with respect to the processing time of the write I / O process. The storage system according to any one of claims 1 to 3, wherein a logical path for performing an I / O process is set. A server that accesses one or more logical disks in a storage device via a plurality of redundant logical paths,
Measuring means for measuring the processing time of the I / O processing of the logical disk for each logical path for each logical disk;
Determining means for determining whether there is a significant difference in the processing time measured by the measuring means between the logical paths;
A setting unit configured to set a logical path for performing I / O processing on the logical disk for which the processing time of the I / O processing is measured based on a determination result of the determination unit; .   When the determination result of the determination means is that there is no significant difference, the setting means uses all logical paths for the logical disk for which the processing time of the I / O processing is measured. 6. The server according to claim 5, wherein a logical path is set so as to perform O processing.   When the determination result of the determination means is that there is a significant difference, the setting means has a performance of the I / O process other than the logical disk on which the processing time of the I / O process is measured. 7. The server according to claim 5, wherein the logical path is set so that I / O processing is performed using a logical path better than the path. The measuring means measures, for each logical path, the processing time of the logical disk read I / O processing and the processing time of the logical disk write I / O processing for each logical path,
Whether the determination unit has a significant difference between the processing time of the read I / O process and the processing time of the write I / O process measured by the measurement unit between the logical paths. Determine whether
The setting means sets the logical disk having measured the processing time of the I / O process based on the determination result with respect to the processing time of the read I / O process and the determination result with respect to the processing time of the write I / O process. The server according to any one of claims 5 to 7, wherein a logical path for performing an I / O process is set. A load balancing setting method for a storage system comprising a storage device and a server that accesses one or more logical disks in the storage device via a plurality of redundant logical paths,
The server is
For each logical disk, measure the I / O processing time of the logical disk for each logical path;
Determining whether there is a significant difference in the measured processing time between the logical paths;
A load distribution setting method comprising: setting a logical path for performing I / O processing on a logical disk for which the processing time of the I / O processing is measured based on a determination result. A method of controlling a server that accesses one or more logical disks in a storage device via a plurality of redundant logical paths,
For each logical disk, measure the I / O processing time of the logical disk for each logical path;
Determining whether there is a significant difference in the measured processing time between the logical paths;
A control method comprising: setting a logical path for performing I / O processing on a logical disk for which the processing time of the I / O processing is measured based on a determination result.

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